(PHILADELPHIA – October 18, 2007) – A new study of immune cells battling a chronic viral infection shows that the cells, called T cells, become exhausted by the fight in specific ways, undergoing profound changes that make them progressively less effective over time.

The findings also point to interventions that would reverse the changes, suggesting that novel therapies could be developed to reinvigorate T cells that become depleted in their struggle against a virus. Alternatively, strategies that would intentionally trigger the immune-dampening mechanisms explored in the study could prove useful in countering autoimmune disorders in which the immune system is inappropriately activated.

Although the experiments were conducted in mice, the problem of T-cell exhaustion has also been identified in HIV, hepatitis B, and hepatitis C infections in humans, as well as some cancers, such as melanoma. A report on the study results appears in the current issue of Immunity, published online October 18.

“We knew that T cells responding to chronic infections become progressively compromised in many of their functional properties,” says E. John Wherry, Ph.D., an assistant professor in the Immunology Program at The Wistar Institute and lead author on the Immunity study. “Put simply, the T cells become exhausted as time passes. What we wanted to learn in our study was what the specific problems were with these cells and whether their depleted state could be reversed.”

Using a technique called gene-expression profiling, Wherry and his colleagues identified 490 genes whose activity in T cells is altered during a chronic viral infection. Closer study at different time points using a 22-gene subset of the larger group of genes provided molecular signatures of progressive T-cell exhaustion. Only a few changes in the activity of the 22 genes were seen at the end of the first week of infection, increasing to 9 differences at two weeks, 18 differences at one month, and 21 differences at two months. At the end of two months, T cells contending with a chronic infection were sluggish metabolically and immunologically unresponsive to stimulus.

One gene identified as playing a central role in this process is called PD-1, which codes for an inhibitory receptor on the surface of the T cells. By blocking PD-1 in vivo, the researchers found they could alleviate T-cell exhaustion, get more functional T cells, and control the infection better.

“Blocking this one pathway partially reverses T-cell exhaustion in some settings, suggesting that we may be able to intervene to reinvigorate depleted immune cells,” says Wherry. “The T cells undergo many changes during chronic infections, however, so that it will be important to learn how to treat them for multiple problems.”

Wherry notes that the mechanisms involved in T-cell exhaustion also have important upsides.

“The flip side of this process is that the immune system has developed an effective way to turn off its response to a stimulus – which is exactly what one wants to do in the case of autoimmunity,” he says.

He points out, too, that the energy outlay during the acute phase of the immune system’s response to an infection is enormous – and fundamentally unsustainable.

“In the first week of an immune response to a virus, T cells can divide every four to six hours, as fast as any other mammalian cell at any time during development,” Wherry says. “In terms of their rate of division, T cells are in the same category as cells in the earliest stages of embryonic development. The energy involved in doing this is extraordinary, and the body can’t keep that up for an extended period of time.”

Wherry is the lead author on the Immunity study, as well as the corresponding author. The senior author was Rafi Ahmed at the Emory University School of Medicine. The co-authors on the study are; Sang-Jun Ha, Surojit Sarkar, Vandana Kalia, and Shruti Subramaniam at Emory; Susan M. Kaech at Yale University Medical School; W. Nicholas Haining at the Dana-Farber Cancer Institute; Joseph N. Blattman at the Fred Hutchinson Cancer Research Center; and Daniel L. Barber at National Institutes of Health.

Funding for the research was provided by the National Institutes of Health, the Foundation for NIH, the Bill and Melinda Gates Foundation, the Elizabeth Glaser Pediatric AIDS Foundation, the Cancer Research Institute, and the Commonwealth Universal Research Enhancement Program of the Pennsylvania Department of Health.

The Wistar Institute is an international leader in biomedical research with special expertise in cancer research and vaccine development. Founded in 1892 as the first independent nonprofit biomedical research institute in the country, Wistar has long held the prestigious Cancer Center designation from the National Cancer Institute. Discoveries at Wistar led to the creation of the rubella vaccine that eradicated the disease in the United States, human rabies vaccines used worldwide, and a new rotavirus vaccine approved in 2006. Today, Wistar is home to preeminent research programs studying skin cancer, lung cancer, and brain tumors. Wistar Institute Vaccine Center scientists are creating new vaccines against pandemic influenza, HIV, and other diseases threatening global health. The Institute works actively to transfer its inventions to the commercial sector to ensure that research advances move from the laboratory to the clinic as quickly as possible. The Wistar Institute: Today’s Discoveries – Tomorrow’s Cures. On the web atwww.wistar.org.

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Featured Image: Horner Brass Microscope

The microscope in the image belonged to William E. Horner, M.D., a collaborator with Caspar Wistar, M.D., in the early 1800s.

Dr. Horner, a lecturer at the University of Pennsylvania, was a pioneer of the use of microscopes in anatomical and medical research. He authored Special Anatomy and Histology, a seminal text on the subject.